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PUBLISHER: WinterGreen Research, Inc. | PRODUCT CODE: 1065473

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PUBLISHER: WinterGreen Research, Inc. | PRODUCT CODE: 1065473

Solid State Batteries: Market Shares, Market Strategies and Forecasts, 2022-2028

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PAGES: 275 Pages; 149 Tables & Figures
DELIVERY TIME: 1-2 business days
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Solid-State Batteries represent next generation automation of electricity storage, a market in line for significant growth. It is expected to grow at a compound annual growth rate (CAGR) of 147.8% from 2021 to 2028. Rising demand for solid-state batteries among end-use sectors along with the rising research and development activities are focused on commercializing the battery. Lower costs for solid state batteries are expected to propel market growth.

EVs represent a primary market. The electrical solid state battery energy industry will reshape the future. The integrated business model of storage is becoming an application for energy consumption. Amid a greater industry focus on battery technology, automakers with EVs in their lineups are scrambling to position themselves for the arrival of solid-state battery cells soon.

As EV sales increase driven by tighter regulation of carbon emissions, solid-state battery makers become indispensable for the renewable energy industry. Solid-state battery products account for a small proportion in the market early on until mass production can be realized. Toyota has a timeline to achieve mass production of solid-state electric vehicle batteries by 2025. ProLogium said it aims to achieve mass produce solid-state batteries in 2022.

With war between Russia and the Ukraine, US President Biden, intent on stopping Putin's aggression, sees that the best way to reduce the price of oil is to shift to renewable energy. Transforming the economy to run electric vehicles, powered by solid state batteries, means that, no one has to worry about gas prices.

Amid a greater industry focus on battery technology, automakers with EVs in their lineups are scrambling to position themselves for the arrival of solid-state battery cells. Ilika, a materials research firm that has helped Toyota develop solid-state batteries, says the carmaker has been working on solid electrolyte technology for 10 years. Toyota's vision is to replace the flammable liquid electrolyte in a lithium-ion battery with a conductive ceramic material.

In Japan, carmakers are rushing to commercialize solid-state batteries. Toyota, Nissan and Honda joined forces with Panasonic to work on solid-state batteries for electric cars. The consortium includes 23 firms in total. They aim to commercialize solid-state batteries in the early 2020ies. The race for the next generation of battery technology is on.

The significant growth of automotive industry in the US, North America, Europe, China, India, Japan, and South Korea is expected to promote the demand for solid state batteries. Amprius Technologies' 100% silicon nanowire batteries are a breakthrough technology that is revolutionizing the battery industry. With the highest energy density, Amprius Technologies batteries improve the performance of electric vehicles, aircraft, drones. Amprius Technologies equipment for high volume manufacturing of 100% silicon nanowire anodes employs inline, continuous, and roll-to-roll production methods.

Worldwide Solid-State Battery markets are poised to achieve remarkable uptake in the market. Next generation Solid-State Batteries promise to bring the biggest change in human labor that has ever occurred.

Silicon anodes energy density is 10 times higher than graphite anodes used in commercial lithium-ion batteries. But silicon anodes negatively affect charging and discharging rates and degrade liquid electrolytes, shortening the battery lifespan. To solve the problem, researchers eliminated carbon and binders from the anode. The team removed the liquid electrolyte and used instead a sulfide-based solid electrolyte and micro-silicon.

These techniques bring the industry closer to realizing all-solid-state battery techniques, greatly diversifying the battery product lineup. Battery manufacturers and automakers around the globe strive to develop a next-generation electric vehicle battery, called an all-solid-state battery (ASSB), which enables longer mileage and a shorter charging time than current EV batteries due to its higher energy density.

The 2022 study has 275 pages, 149 tables and figures.

Product Code: SH29551314

Table of Contents

Abstract: Russia Attack on Ukraine Brings Urgency to Renewable Energy Implementation: Solid State Batteries Bring Reliability and Longevity to Energy Supply 1

Solid State Battery Executive Summary

  • Solid State Batteries Energy Density and Longer Range

1. Solid-State Battery Market Definition and Market Dynamics

  • 1.1 New Solid State Battery Chemistries
  • 1.2 Batteries with Solid-State Electrolytes Inherently Safer
    • 1.2.1 Solid-State Battery Is a Cell Without Any Liquid or Gel Electrolytes
  • 1.3 Electric Vehicles to Use Solid-State Batteries

2. Solid State Battery Market Shares and Forecasts

  • 2.1 Solid-State Battery Market Driving Forces
    • 2.1.1 Advantages of Solid-State Batteries
    • 2.1.1 Disadvantages of Lithium-ion Batteries
  • 2.2 Solid State Battery Market Shares
  • 2.3 Solid State Battery Market Forecasts
  • 2.4 Solid State Battery Market Segments
    • 2.4.1 Global Solid State Battery Market
  • 2.5 Solid State Battery Regional Analysis

3. Solid State Battery Product Developments

  • 3.1 Companies Embrace Renewable Energy
    • 3.1.1 Anheuser-Busch
  • 3.2 New 4680 Tesla Batteries Vs. Solid-State Batteries
  • 3.3 Ship Filled with Porsches and Bentleys Has Lithium Batteries Catch Fire
    • 3.3.1 Ship Fire
  • 3.4 Using Light with Batteries

4. Solid State Battery Research and Technology

  • 4.1 Silicon Battery Technology
    • 4.1.1 Silicon Nanowire
  • 4.2 Samsung Develops Solid-State Cell with Silver / LG Researchers Eliminate Carbon and Binders from The Anode
  • 4.3 Amprius Silicon Nanowire Batteries
  • 4.4 ProLogium Core Technologies Ceramic SSBs
  • 4.5 Bolloré Group
  • 4.6 Materials for Use as Solid Electrolytes
  • 4.7 Solid Power Solid State Battery Technology
  • 4.8 Japan's Tohoku University Hydride Lithium Superionic Conductor
    • 4.8.1 Complex Hydrides
  • 4.9 Amprius® Technologies Stores Lithium in Tiny Silicon Nanowires
  • 4.10 BMW Lithium Metal Battery
  • 4.11 Quantum scope Solid State battery
  • 4.12 Comparing Separator Materials

5. Solid State Battery Company, University, and Government Agency Profiles

  • 5.1 24M
  • 5.2 Amperex Technology Ltd. (CATL)
    • 5.2.1 CATL Initial Public Offering in Shenzhen
  • 5.3 Amprius
    • 5.3.1 Amprius Technologies Corporate Headquarters in Fremont, California
  • 5.4 Apple
  • 5.5 Aurora
  • 5.5.1 Northvolt
  • 5.5.2 Galp
  • 5.6 BASF
  • 5.7 Bettergy
  • 5.8 BOAO Navigator Battery Holding
  • 5.9 Bolloré
    • 5.9.1 Bolloré Group Revenue
    • 5.9.2 Bolloré BlueCar
    • 5.9.3 Autolib Blue Solutions
    • 5.9.4 Blue Solutions Solid State Battery Development
    • 5.9.5 Bolloré Solid State Battery Production Capacity
    • 5.9.6 Autolib Red Car Solutions
    • 5.9.7 Bollore Energy Storage Ringo Project by RTE
  • 5.10 BMW
  • 5.11 Bosch
  • 5.12 BYD
  • 5.13 California Energy Commission
  • 5.14 Cymbet
  • 5.15 Dyson / Sakti3
  • 5.16 Enevate
    • 5.16.1 EV Battery Equivalent of a Gas Tank. In Addition, It Provides the Vehicle Powertrain
    • 5.16.2 Now's the Time to Replace Cars That Run on Fossil Fuels with EVs
    • 5.16.3 Extreme Fast Charging Technology Changes Everything
  • 5.17 Enovate
  • 5.18 Factorial Energy
    • 5.18.1 Factorial's new Solid-State EV Battery
  • 5.19 Ford
  • 5.20 FREYR Battery
    • 5.20.1 Alussa Energy
    • 5.20.2 FREYR A/S
    • 5.20.3 Alussa Energy Acquisition Corp.
  • 5.21 Front Edge Technology
    • 5.21.1 Front Edge Technology Technical Information
  • 5.22 General Motors Collaborating with LG Energy Solution on Solid State Batteries
    • 5.22.1 GM Ultium Lithium-Ion Battery
  • 5.23 Honda
  • 5.24 Hyundai
  • 5.25 Ilika
  • 5.26 Ion Storage Systems
  • 5.27 Ionic
  • 5.27.1 Ionic Materials Liquid Crystal Polymer
  • 5.28 Jiawei
  • 5.29 Johnson Battery Technologies
  • 5.30 LG
  • 5.31 Lishen
  • 5.32 Mercedes-Benz
  • 5.33 MIT
  • 5.34 Mitsui Kinzoku
  • 5.35 Mobis Energy
  • 5.36 Mullen Automotive
  • 5.37 Nissan
  • 5.38 Northvolt
    • 5.38.1 Northvolt / Cuberg
  • 5.39 Panasonic
    • 5.39.1 Panasonic Leader in Lithium-Ion Battery Market by Virtue of Its Position as A Supplier to Tesla
  • 5.40 Pellion
  • 5.41 PolyPlus
    • 5.41.1 PolyPlus Battery Company Joint Development Agreements, One with SK Innovation Co. Ltd.,
  • 5.42 ProLogium
    • 5.42.1 ProLogium and Mercedes-Benz Technology Cooperation Agreement to Develop Solid-State Battery Cells for Electric Vehicles
    • 5.42.2 ProLogium and Mercedes-Benz Agreed on Milestones
    • 5.42.3 Softbank Backs ProLogium
    • 5.42.4 ProLogium Major Product Pipelines
    • 5.42.5 ProLogium Production Capacity Able to Meet Their Demand for Solid-State Batteries
  • 5.43 QuantumScape
  • 5.44 Riverstone Holdings' Decarbonization Plus Acquisition Corporation III
  • 5.45 Sony
  • 5.46 Total / Saft
  • 5.47 Sakti3
  • 5.48 Samsung
  • 5.49 SK Innovation
  • 5.50 Schneider Electric
    • 5.50.1 Schneider Electric Positions to Implement Electrification of Society At Large
  • 5.51 Seeo
  • 5.52 Sila Nanotechnologies and Enivate
  • 5.53 Sion Power
    • 5.53.1 Sion Power Chemically Stable Ceramic Barriers
  • 5.54 SK Innovation
  • 5.55 SolidEnergy Systems
  • 5.56 Solid Power
    • 5.56.1 Solid Power Technology
    • 5.56.2 Solid Power Teaming with Ford and BMW
    • 5.56.3 Samsung and Hyundai / Solid Power
  • 5.57 Stanford TomKat Center
  • 5.58 Sumitomo Electric Industries
  • 5.59 SUNY
  • 5.60 Tesla
    • 5.60.1 Tesla Canada Industrial Research Chair, Canada Research Chair, Dalhousie University
  • 5.61 Thermo Scientific
    • 5.61.1 Thermo Scientific Medical Spectrometers
  • 5.62 Total Energies / Saft
  • 5.63 Toyota
  • 5.64 US Department of Energy
  • 5.65 US Military
  • 5.66 LG / University of California at San Diego
    • 5.66.1 LG Silicon Anodes
    • 5.66.2 Silicon As an Anode to Replace Graphite
  • 5.67 University of Illinois at Urbana
  • 5.68 University of Texas All-Solid-State Lithium-Ion Battery Cell
  • 5.69 Volkswagen Group
  • 5.70 Wildcat Discovery Technologies

6. Table of Contents

  • Table of Contents
  • List of Tables and Figures
  • 6.1 Selected Companies Participating in the Solid-State Battery Market

WinterGreen Research,

  • WinterGreen Research Methodology
  • WinterGreen Research Process
  • Market Research Study
  • WinterGreen Research Global Market Intelligence Company
  • Report Description: Revenue Models Matter
Product Code: SH29551314

LIST OF TABLES AND FIGURES

  • Abstract: Russia Attack on Ukraine Brings Urgency to Renewable Energy Implementation: Solid State Batteries Bring Reliability and Longevity to Energy Supply 1
  • Figure 1. Hilary Maxson MBA Executive Vice President and Group Chief Financial Officer at Multinational Electrification Schneider Electric
  • Figure 2. Sumitomo Electric Industries All-Solid-State Lithium Battery Problems
  • Figure 3. Materials Used as Electrolytes in Solid-State Batteries
  • Figure 4. Renewable Energy Storage Metrics
  • Figure 5. Solid-State Battery Market Driving Forces
  • Figure 6. Advantages of Solid-State Batteries
  • Figure 7. Disadvantages of Solid-State Batteries
  • Figure 8. Solid State Battery Market Shares, Dollars, Worldwide, 2021
  • Figure 9. Solid State Battery Market Shares, Dollars, Worldwide, 2021
  • Figure 10. Solid State Battery Company Descriptions, Worldwide, 2021
  • Figure 11. Solid State Batteries Have Their Own Issues, Such as A Shorter Service Life
  • Figure 12. Selected Solid State Battery Market Leaders Company Description, Worldwide, 2022 (1)
  • Figure 13. Selected Solid State Battery Market Leaders Company Description, Worldwide, 2022 (2)
  • Figure 14. Selected Solid State Battery Market Leaders Company Description, Worldwide, 2022 (3)
  • Figure 15. Selected Solid State Battery Technology Solution Metrics Worldwide, 2022
  • Figure 16. Selected Solid State Battery Technology Solution Metrics, Worldwide, 2022 (2)
  • Figure 17. Cathode Market Shares, Dollars, Worldwide, 2021
  • Figure 18. Cathode Market Positioning Descriptions, Worldwide, 2021
  • Figure 19. Solid State Battery Market Forecasts, Dollars Shipped, Worldwide, 2020-2026
  • Figure 20. Solid State Battery Segments, Electric Vehicle, Stationary Storage / Grid, Smart Phones, Power Tools, Laptops, Consumer Electronics, Military / Navy / Drones / UUVs / UAVs, Market Segments, Dollars, Worldwide, 2022-2028
  • Figure 21. Solid State Battery Segments, Electric Vehicle, Smart Phones, Stationary Storage / Grid, Power Tools, Laptops, Consumer Electronics, Military / Navy / Drones / UUVs / UAVs, Market Segments, Units Shipped, Worldwide, 2022-2028
  • Figure 22. Solid State Battery Segments, Electric Vehicle, Stationary Storage / Grid, Smart Phones, Power Tools, Laptops, Consumer Electronics, Military / Navy / Drones / UUVs / UAVs, Market Segments, Percent, Worldwide, 2020-2026
  • Figure 23. Other Solid State Battery Market Segments
  • Figure 24. Solid State Battery Regional Market Segments, Dollars, Worldwide, 2021
  • Figure 25. Solid State Battery Regional Market Segments, Dollars, Worldwide, 2021
  • Figure 26. Germany Plans to Speed Up Wind and Solar Projects as It Seeks to Curb Its Dependence on Russian Energy
  • Figure 27. Cargo Ship Carrying Porsches and Bentleys Burning and Adrift at Sea
  • Figure 28. Benefits of Using Nanowires in Li-Ion Batteries
  • Figure 29. Materials for Use as Solid Electrolytes in Solid-State Batteries
  • Figure 30. Benefits of Using Nanowires in Solid State Batteries
  • Figure 31. Cross Sectional Image of Amprius Technologies' Silicon Nanowire Anode using a Scanning Electron Microscope
  • Figure 32. Amprius Technologies' Silicon Nanowire Anode
  • Figure 33. Advantages of Amprius Technologies 100% Silicon Nanowire Batteries
  • Figure 34. Amprius Technologies' Silicon Nanowire Anode Li-ion Cells
  • Figure 35. Amprius Technologies' Cells vs. Tier -1 Energy Density
  • Figure 36. Next Generation Cathode Material or Next Generation Anode Material
  • Figure 37. QuantumScape Solid State Battery
  • Figure 38. Lithium-Metal Anode Enabled by A Solid-State Separator Benefits
  • Figure 39. The Promise of Solid-State Lithium-Metal Batteries
  • Figure 40. Solid State Battery Separator Materials
  • Figure 41. Solid State Battery Systems Using Separator Materials
  • Figure 42. QuantumScape Solid-State Landscape
  • Figure 43. 24M SemiSolidTM battery
  • Figure 44. 24M SemiSolidTM Battery Cell Manufacturing
  • Figure 45. 24M Solid State Battery Manufacturing
  • Figure 46. 24M Partners
  • Figure 47. Amprius Technologies 100% Silicon Nanowire Battery Technology
  • Figure 48. Amprius® Technologies 500 Wh/kg Batteries Provide Ultra-High Energy Density and Excellent Cycle Life
  • Figure 49. Amprius Technologies Market Segments
  • Figure 50. Applications Currently Using Amprius Technologies Batteries
  • Figure 51. Northvolt Key Customers
  • Figure 52. BOAO Navigator Battery
  • Figure 53. Linghang Boao Group Headquarters
  • Figure 54. Linghang Boao Group Test Results
  • Figure 55. Linghang Boao Group Energy Series
  • Figure 56. Linghang Boao Group Ultra-Thin Series
  • Figure 57. Linghang Boao Group Fast Charging Series
  • Figure 58. Linghang Boao Group Safety Inspection
  • Figure 59. Linghang Boao Group Test Results
  • Figure 60. Linghang Boao Group Energy Storage Regional Presence
  • Figure 61. Bolloré BlueCar in France, with Solid State Battery Developed for a Car-Sharing Service
  • Figure 62. Bollore's Solid-State Batteries for Electric Cars
  • Figure 63. Bollore Solid State Battery Technology
  • Figure 64. Bollore All-Solid Cell Benefits
  • Figure 65. Bolloré Extrusion of Ultra-Thin Film Anode, Electrolyte, and Cathode Layers
  • Figure 66. Bollore LMP® Technology: A Ground-Breaking Solution for Electric Urban Transport
  • Figure 67. Bollore Partners for Bus Manufacture
  • Figure 68. Benefits Of Solid-State Batteries Compared to Traditional Li-ion Technologies
  • Figure 69. Advantages Of Solid-State Batteries Compared to Traditional Li-ion Technologies
  • Figure 70. Bolloré Benefits of Solid-State Batteries
  • Figure 71. Bollore Innovative Storage Systems in Europe
  • Figure 72. BMW Solid Power Solid-State Batteries
  • Figure 73. Cymbet EnerChip Applications Power Characteristics
  • Figure 74. Cymbet EnerChip Device Applications
  • Figure 75. Enevate Investors
  • Figure 76. Fast Charge needed for Long-Range Vehicle and City Vehicle
  • Figure 77. Enevate Addresses Pain Points for EV Adoption:
  • Figure 78. Enevate Delivers:
  • Figure 79. Images of the Enovate Electric Car Powered by a Solid-State Battery
  • Figure 80. Enovate Electric Car Interior
  • Figure 81. Factorial Energy Solid State Battery
  • Figure 82. Factorial Energy Solid State Battery Benefits
  • Figure 83. Factorial Solid State Battery Cells Advantages
  • Figure 84. Ford's View of Renewable Energy Storage Metrics
  • Figure 85. Ford & BMW Plan to Begin Testing Solid Power Batteries In 2022
  • Figure 86. FREYR Battery
  • Figure 87. Front Edge Technology NanoEnergy® Micro Device Rechargeable Battery
  • Figure 88. Ionic Materials Solid State Battery
  • Figure 89. GM Ultium Lithium-Ion Battery
  • Figure 90. GM Ultium Battery on Chassis
  • Figure 91. Ionic Materials is Working on a Solid-State Battery
  • Figure 92. Jiawei Solid State Battery Positioning
  • Figure 93. Jiangsu Solid-state Battery Base
  • Figure 94. Johnson Energy Storage.
  • Figure 95. Mercedes-Benz Investment into Solid-State Battery Developer ProLogium
  • Figure 96. MIT Pulsed Laser Deposition to Make Thinner Lithium Electrolytes for Solid-State Lithium-Ion Batteries
  • Figure 97. MIT Optical Microscopy Image of a Solid Lithium Garnet (LLZO) Thin-Film Electrolyte Deposited on A Magnesium Oxide (MgO) Substrate.
  • Figure 98. Mitsui Solid-State Battery Configuration
  • Figure 99. Mobis Energy Battery Module for eVTOL
  • Figure 100. Mullen Automotive Battery Metrics
  • Figure 101. Nissan Micra Solid State Battery
  • Figure 102. Nissan Solid State Battery
  • Figure 103. Northvolt Facility
  • Figure 104. Mobis Energy Battery Module Metrics for eVTOL
  • Figure 105. Northvolt Battery Customers
  • Figure 106. Volkswagen Production Line
  • Figure 107. Cuberg Solid State Batteries
  • Figure 108. Panasonic Partners to Work on Solid-State Batteries
  • Figure 109. Mercedes, ProLogium Pair Up on Solid-State Battery Tech
  • Figure 110. ProLogium Solid-State Battery Tech
  • Figure 111. ProLogium Headquarters
  • Figure 112. ProLogium PLG's offers BiPolar+ 3D Structure Solid-State EV Battery Pack
  • Figure 113. ProLogium Solid State Battery Applications: UPS, AVG, Solar Street Lights, Consumer Electronics, Electric Vehicles, Rideshare Vehicles
  • Figure 114. ProLogium Solid State Battery Applications: Energy Storage System, Yacht, Telecom Towers, Solar and Wind Energy System, Touring Car
  • Figure 115. ProLogium Solid State Battery
  • Figure 116. ProLogium Battery Comparison Table
  • Figure 117. Key remaining Tasks for QuantumScape
  • Figure 118. QuantumScape Solid State Batteries
  • Figure 119. Solid Power High-Content Silicon All-Solid-State Batteries in Front of a Coated Silicon Electrode Layer
  • Figure 120. Samsung Solid State Battery
  • Figure 121. SK Innovation Superior Energy Density
  • Figure 122. SK Innovation Battery Cell in Production
  • Figure 123. NMC Composition Diagram Illustrates Less Cobalt (Co) Means Lower Cost
  • Figure 124. Lithium-ion Battery Material Development and Cell Roadmap
  • Figure 125. Hilary Maxson MBA Executive Vice President and Group Chief Financial Officer at Multinational Electrification Schneider Electric
  • Figure 126. Schneider Electric Solar Panel Charging Stations
  • Figure 127. Sila Nanotechnologies and Enivate Solid State Battery
  • Figure 128. Sion Power Licerion® Battery
  • Figure 129. Sion Power Battery Metrics
  • Figure 130. Sion Power Images
  • Figure 131. Sion Power Technology Images
  • Figure 132. Sion Power Lithium Metal Technology Images
  • Figure 133. Sion Power Battery Packs Can Be Linked Together
  • Figure 134. SK Innovation Auto Maker Partners: Hyundai Motor Group, BAIC Group, and Daimler AG
  • Figure 135. Solid Power All Solid-State Batteries
  • Figure 136. Solid Power Factory
  • Figure 137. Sumitomo Electric Industries All-Solid-State Lithium Battery Problems
  • Figure 138. Sumitomo Solid State Battery Wiring Module Mounted on High-Voltage Battery
  • Figure 139. Sumitomo Solid State Battery Wiring Module Is Its Flexible Adaptation to Different Combinations of Cells (Cell Stacks, Which Are Also Known As "Battery Modules"
  • Figure 140. Sumitomo Electric Industries All-Solid-State Lithium Battery Solutions to Issues
  • Figure 141. SUNY at Binghamton Northeast Center for Chemical Energy Storage (NECCES) Funding US Department of Energy
  • Figure 142. Tesla 4680 Batteries
  • Figure 143. Thermo Fisher Scientific Solid-State Battery Microscopic and Spectroscopic Analysis
  • Figure 144. Saft Metrics
  • Figure 145. Toyota Prototype EV Equipped with a Solid-State Battery
  • Figure 146. US Department of Energy DOE $175 Million for 68 OPEN 2021 Research to Strengthen Advanced Energy
  • Figure 147. High Performance All-Solid-State Battery with A Pure-Silicon Anode
  • Figure 148. Micro Silicon Anode: Description of the Image
  • Figure 149. University of Illinois at Urbana - Champagne. Dynamic Networks for Solid Polymer Electrolytes
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